module components are packaged individually and delivered in a non-integrated state. These separate modules may be assembled readily without the use of specialized tools. A preferred configuration is a solid ink printer base module and a second module mounted to the base module through a quick coupling, quick release mechanism. The coupling mechanism may include a hinge and a self-actuating catch. A module coupling system with complementary parts on each module comprises: a first module having a coupling housing and a catch engagement surface, and a second module having a physical, three-dimensional guide surface, a biased retractable catch, a catch decoupling device, and a catch reset mechanism.
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1. A module coupling system for coupling two separate modules, comprising:
a first module having
a coupling housing with projecting arms that extend beyond the housing;
a catch engagement surface; and
a second module having
a physical three-dimensional guide surface oriented along a longitudinal axis, the guide surface defining a support landing pad for the coupling housing of the first module on one end and a shoe housing on the other end that at least partially receives the coupling housing;
a retractable catch movable between a catch enabled position capable of mating with the catch engagement surface of the first module and a latched, decoupled position at which the retractable catch is decoupled from the catch engagement surface of the first module;
a catch decoupling device that is movable to position the retractable catch at the latched, decoupled position to decouple the retractable catch from the catch engagement surface; and
a catch reset mechanism that automatically resets the retractable catch to the catch enabled position upon removal of the first module.
13. A field-assembled component reprographic device, comprising:
a first component module forming a upper reprographic device having a coupling housing with projecting arms that extend beyond the housing and a catch engagement surface; and
a second, separate component module forming a reprographic device base module having
at least one physical three-dimensional guide surface oriented along a longitudinal axis, the guide surface defining a support landing pad for a corresponding coupling housing of the first module on one end and a shoe housing on the other end that at least partially receives the coupling housing;
a retractable catch provided on the guide surface and movable between a catch enabled position capable of mating with the catch engagement surface of the first component module and a latched, decoupled position at which the retractable catch is decoupled from the catch engagement surface;
a catch decoupling device that is movable to slide the retractable catch to the latched, decoupled position to decouple the catch from the catch engagement surface; and
a catch reset mechanism that automatically resets the retractable catch to the catch enabled position upon removal of the first module,
wherein the first module may be positively coupled to the second module by positioning of the first module relative to the second module so that the coupling housing is lowered into contact with the support landing pad and the coupling housing is then slid along the longitudinal axis until the catch is engaged with the catch engagement surface of the first module to lock the first module in place relative to the second module.
2. The module coupling system for coupling two separate modules according to
3. The module coupling system for coupling two separate modules according to
4. The module coupling system for coupling two separate modules according to
5. The module coupling system for coupling two separate modules according to
6. The module coupling system for coupling two separate modules according to
7. The module coupling system for coupling two separate modules according to
8. The module coupling system for coupling two separate modules according to
9. The module coupling system for coupling two separate modules according to
10. The module coupling system for coupling two separate modules according to
11. The module coupling system for coupling two separate modules according to
12. The module coupling system for coupling two separate modules according to
14. The field-assembled component reprographic device according to
15. The field-assembled component reprographic device according to
16. The field-assembled component reprographic device according to
17. The field-assembled component reprographic device according to
18. A method of assembling the component field-assembled reprographic device of
positioning the first module above the second module;
aligning the at least one coupling housing with the corresponding guide surface;
lowering the first module until the at least one coupling housing is supported on the landing pad of the second module; and
sliding the first module along the guide surface until the retractable catch is received within a retractable catch receiving pocket of the first module containing the catch engagement surface.
19. A method of disassembling the component field-assembled reprographic device of
disengaging the retractable catch by moving the catch decoupling device having an inclined ramp profile that positions the retractable catch at the latched, decoupled position;
sliding the first module along the guide surface onto the landing pad; and
lifting the first module from the second module.
20. The method of disassembling the component field-assembled reprographic device of
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The invention relates to a quick coupling/decoupling mechanism for units that may be assembled by unskilled users. The coupling mechanism may or may not include a hinge function. As a hinging motion is easily incorporated and provides additional functionality, the invention will be described chiefly in that context. The hinge assembly is particularly suited for releasably coupling a first pivoting module to a base module. The hinge assembly may include a self-actuating catch that locks the hinge in a closed position when the upper module is detached from the base module.
Larger systems with modules that cannot be assembled as shipped from the factory place a burden on customers to do assembly steps they may not typically be qualified to perform. This is especially problematic if the operation of or safety of the system or modules being assembled could be compromised as a consequence of incorrect or incomplete assembly.
Printers, copiers, facsimiles and other reprographic products typically have a cover or structural housing that has to be pivoted open to gain access to internal components, such as for ink or toner replenishment, media jams, etc. Copiers and multifunctional printers and devices with printing, scanning and/or copying functions have additional requirements for pivoting covers. Such multifunction devices besides having printing mechanisms may also include scanning mechanisms and may have a feed unit with automatic document feeding mechanisms. The feed unit is normally oriented in a nearly horizontal position. Such feed units must be pivoted open to access a scanner platen glass for document copying or media jam recovery.
Thus, in a reprographic device in which a cover module must be hinged for rotation during normal usage, improper or incomplete assembly of the cover module by a customer may result in serious damage to the various module components, and could pose serious safety concerns to the users of the device should the device not be properly and positively assembled. This is particularly true of devices that move through an extended access pivot range, up to and beyond 90° and are large and/or massive.
Another concern over a product that requires more than nominal assembly by a customer is the customer's response to the actions necessary to place the product in use. Many customers are not tolerant of inappropriate burdens or complex assembly steps.
Accordingly, it would be advantageous to provide a hinged multi-module product with easier assembly steps. Moreover, in light of safety and operation concerns, it would be advantageous to provide a product having not only simple assembly, but an assembly that can ensure reliable, positive latching, even with inexperienced users.
In accordance with various aspects, hinged module components are packaged individually and delivered in a non-integrated state. In various exemplary embodiments, such separate modules may be assembled readily without the use of specialized tools. In various embodiments, the separate modules may be a base module, such as a reprographic device, and a hinged pivoting module, such as a cover module or a more complex scanning or document feeding assembly mounted to the base module through a detachable hinge assembly.
Orientation and placement of various interrelated but separate modules for assembly can be a difficult task for customers unfamiliar with a product. Thus, common assembly solutions such as a thumbscrew or keyslot can be very unreliable, particularly with large and/or bulky modules where visibility to points of concern is less than optimal. Moreover, thumbscrews and similar “latch after placement” retention structures are often all too easy to improperly or incompletely engage or tighten. Accordingly, there is also a need for a reliable assembly method and structure that can result in simple, positive, reliable retention of module assemblies by a customer or technician.
In accordance with various aspects, a quick coupling mechanism having mount and locate features is provided on separate module components to allow for easy alignment and assembly of the module components in the field.
In accordance with various aspects, a quick coupling mechanism provides a base module with a “set down” landing pad and shoe for receiving a mating “foot print” structure of a corresponding module to be integrated with the base module. In exemplary embodiments, the set down landing pad may accommodate support and initial positioning functions for the corresponding module to encourage correct module orientation and alignment. The set down landing pad can then assist in guiding the corresponding module into a secure positive engagement of the corresponding module within the shoe of the base module.
In preferred exemplary embodiments, the “set down” landing pad provides a support mechanism for the assembler that supports a majority of the weight of the upper module during slide coupling. This allows for the assembly of even heavy module components because the assembly does not need to be supported by the customer during the entire assembly process. Moreover, because the weight is supported, it may become easier for the customer to make any necessary relative position corrections to the module prior to full locking assembly of the module components. Thus, in various embodiments, assembly can be achieved with a set down and slide movement that does not require lifting or supporting of the module during the slide alignment. This provides a higher reliability of alignment and positive coupling.
In exemplary embodiments, the modules may be provided with a securely coupled catch that can automatically lock one module against removal from the other module. In a preferred embodiment, the catch is near a point where sliding engagement reaches a hard stop.
In accordance with various aspects, when the module “foot” is inserted into the complementary “shoe” support of the other module, the guided module may have its movement severely constrained. For example, a “heel” catch may be provided that engages with a rear portion of the guided module, which prevents rearward movement of the module. Moreover, by providing a front stop that limits forward movement and optionally, lateral movement, the two modules can be quickly guided into a positive locking and secure configuration through simple slide and latch movements. Accordingly, assembly can be reliably performed by customers without the need for tools or complex assembly procedures.
Visual indicators may be provided at each of two widely separated parallel coupling assemblies to provide positive feedback that a desired locked condition has been attained. These visual indicators are preferably a component of the pivoting catch so that the visual indication of a locked state cannot occur unless the module being coupled is fully in place. Failure to attain the visual lock indication requires that a further nudge of the module is needed on the side not visibly locked. Adequately applied, this further motion will result in full engagement with visual lock verification. Additionally, visual indicators can be used for initial placement on the landing pad with a correct orientation and alignment.
In exemplary embodiments, removing the coupled module is accomplished by simply sliding a catch latch to a release position, such as with any small object like a screwdriver, Allen wrench, pen, paper clip or the like to unlock the coupling. The catch release may be designed to latch in the unlocked position so that the user does not have to hold it. As the module is slid out of the constraining features of the catch, the lock enabled state of the catch is automatically returned so that it is ready to relock the module when reassembled.
In exemplary embodiments, a module coupling system with complementary parts on each module comprises: visual and physical guide features to align the modules for assembly; position constraining guides to facilitate convenient sliding insertion into a locking position; a module locking catch with integral visual lock position indicator; a decouple catch release mechanism that allows any small cylindrical or pointed object to be used to slide the catch release to a latch position where the modules can be removed without holding the catch release; and a latch release trigger that enables the coupling catch to automatically return to a module receiving and catch enabled state as the module is removed.
In exemplary embodiments, a module coupling system for separately provided module components comprises: a module coupling system for coupling two separate modules, comprising: a first module having a coupling housing with projecting arms that extend beyond the housing; a latch engagement feature such as a receiving pocket for a retractable catch; and a second module having a physical three-dimensional guide surface oriented along a longitudinal axis, the guide surface defining a support landing pad for the coupling housing of the first module on one end and a shoe housing on the other end that at least partially receives the coupling housing; a retractable catch movable between a released position and a latched position; and a visual indicator that indicates movement of the retractable catch to the latched position, wherein the first module is positively coupled to the second module by positioning of the first module relative to the second module so that the coupling housing is lowered into contact with the support landing pad and the coupling housing is then slid along the longitudinal axis until the retractable catch is received within the retractable catch receiving pocket of the first module to lock the first module in place relative to the second module, the visual indicator indicating movement to the latched position. The term pocket is used for convenience but the catch engagement feature could be a tab, pin, rib or other configuration that provides the ability to prevent sliding motion when acted upon by the catch.
In exemplary embodiments, a field-assembled component reprographic device is provided that includes: a first component module forming a reprographic device cover having at least one hinged coupling housing with projecting arms that extend beyond the housing, the hinged coupling having an upper housing pivotally connected to a lower housing by a pivot shaft, a catch feature, such as a pin provided on one of the upper and lower housings and a pivoting catch provided on the other of the upper and lower housings, the pivoting catch being biased to latch around the catch pin and lock the upper housing to the lower housing; and a pocket for receiving a retractable catch; and a second, separate component module forming a reprographic device base module having at least one physical three-dimensional guide surface oriented along a longitudinal axis, the guide surface defining a support landing pad for a corresponding coupling housing of the first module on one end and a shoe housing on the other end that at least partially receives the coupling housing; a retractable catch provided on the guide surface and movable between a released position and a latched position; and a visual indicator that indicates movement of the retractable catch to the latched position, wherein the first module may be positively coupled to the second module by positioning of the first module relative to the second module so that the coupling housing is lowered into contact with the support landing pad and the coupling housing is then slid along the longitudinal axis until the retractable catch is received within the pocket for receiving a retractable catch of the first module to lock the first module in place relative to the second module, the visual indicator indicating movement to the latched position, further wherein when the first module is coupled to the second module, the lower housing is at least partially received within the shoe housing and the upper housing is located above the shoe housing and the shoe housing and catch are arranged such that the shoe housing engages the catch to release engagement from the catch pin, allowing free rotation of the upper housing relative to the lower housing.
In various embodiments, methods of assembly and disassembly of module components are provided.
Exemplary embodiments will be described with reference to the drawings, wherein:
The upper pivoting unit 210 may form a simple platen cover or an upper feeder unit having an auto feeding module that advances a recording media, such as paper, past a scanning head or scan platen. In an exemplary embodiment, the lower pivoting unit 220 forms a lower scan unit that contains the scanner platen. The scanned images can be reproduced by a marking engine provided in, for example, base 230.
First coupling hinge assembly 300 can take any conventional or subsequently developed form and allows rotational movement of upper pivot module 210 between a substantially horizontal closed position and a substantially vertical fully open position. However, module 210 may also be positioned at one or more intermediate positions. The functions and advantage of the coupling assembly 400 is applicable for quick secure coupling of two modules in the absence of an upper pivoting unit 210 and independent of the need for relative pivoting motion between units.
Second coupling hinge assembly 400 likewise allows rotation of lower pivoting module 220 between a closed substantially horizontal position (
As illustrated in the simplified representations of
As shown in
Movement of the hinge assembly is controlled by cam 440 having a cam profile 442. Upper housing 420 includes a spring 424 and may, as necessary based on module mass and geometry, include a second spring 422 that bias a cam follower/plunger 426 against the cam profile 442 to control movement of the upper housing 420 between a closed position, in which the upper housing 420 is substantially parallel with the lower housing 410, and an open position, in which the upper housing 420 is at substantially a right angle to lower housing 410.
In a preferred embodiment, the hinge assembly 400 is provided with a biased lock that releasably locks the hinge assembly 400 in the closed position. This is particularly useful to prevent activation of the hinge assembly when the upper module is detached from the lower module. This also ensures a consistent orientation of the hinge and associated module for assembly or disassembly. The biased lock in an exemplary embodiment includes a pivoting latch 450 that engages a latch pin 460, which could also be a formed sheet metal protrusion or similar feature, to retain the upper and lower housings 420, 410 in fixed relationship. Pivoting latch 450 can be biased to the latched position by a suitable biasing element, such as a spring 470 coupled between the hinge latch 450 and lower housing 410. In this embodiment, spring 470 is attached to a suitably shaped protrusion 452 on the hinge latch and connected to housing 410 by a similar feature on housing 410. A spring screw 490 may be provided to hold the cam in place during assembly. A catch mating or engagement surface 480 may be formed on housing 410, such as an upward fold that provides a vertical engagement surface for mating with corresponding catches on the base module 230. Additionally, lower housing 410 can include a protrusion forming a coupling catch reset 485, as shown in
Details of an exemplary guide coupling mechanism will be better described with reference to
Raised guide support surfaces 510 serve as a convenient “set down” landing pad on which the hinge assemblies 400 may be individually supported prior to installation. In accordance with various aspects, the set down landing may accommodate support and initial positioning functions for the corresponding upper module to encourage correct module orientation. In the illustrated embodiment, the protruding arms 414 are spaced to fit closely on each side of guide surface 510 to support and constrain movement of hinge assembly 400 substantially in line with guide surface 510.
In preferred exemplary embodiments, the “set down” landing pad surface 510 provides a support mechanism for a component assembler that supports a majority of the weight of the upper module 220 during slide coupling. This allows for the assembly of even heavy module components because the assembly does not need to be supported by the customer during the entire assembly process. Moreover, because the weight is supported, it may become easier for the customer to make any necessary relative position corrections to the module prior to full locking assembly of the module components.
In accordance with various aspects, when the module “foot” (hinge assembly 400) is inserted into the complementary quick coupling mechanism 500 of the other module, the guided module (220) may have its movement severely constrained. For example, guide surface 510 and arms 414 restrict lateral movement and allow primarily axial movement along guide surfaces 510. Upon full insertion of the hinge assembly 400 into the coupling mechanism 500, the protruding arms 414 engage features 560 and restrict vertical movement. Additionally, biased catches 530 engage with engagement surfaces 480. This constrains rearward movement in the direction of the guide to positively lock the hinge assembly 400 to the lower module 230. Thus, the two modules (220, 230) can be quickly guided into a positive locking and secure configuration through simple slide and latch movements.
In exemplary embodiments, one or more structures may act as a front stop. For example, protruding arms 414 can serve as a “heel” catch that engages with a heel catch engagement point 560 on the quick coupling mechanism 500 near the front of the shoe housing 520. Alternatively, housing 520 may have a back wall that abuts a front wall of lower hinge housing 410 to provide a front stop that limits forward movement. Similarly, lateral movement may be constrained by the side walls of housing 520 and/or arms 414 mating with guide surface 510. Thus, in exemplary embodiments, the two separate modules (220, 230) may be provided with a secure catch and positioning structure that can automatically lock one module against removal from the other module. In a preferred embodiment, the catch is near a point where sliding engagement reaches a hard stop.
A better understanding of the sliding action of the exemplary quick coupling mechanism can be seen in
Positive coupling can be achieved with two simple movements. First, the upper module having hinge assemblies 400 thereon is positioned above base module 230 and lowered onto the landing pad guide surface 510 by application of downward force F1, resulting in the position shown in
Visual indicators may be provided at each of two widely separated parallel coupling assemblies to provide positive feedback that a desired locked condition has been attained. These visual indicators, such as indicators 600, are preferably a component of the pivoting catches 530 so that the visual indication of a locked state cannot occur unless the module being coupled is fully in place (i.e., catches 530 is fully received and locked within pockets 480). That is, upon full locking of pivoting catches 530 against engagement surfaces 480, visual indicators 600 will be moved to a position above the guide surface 510, as shown, by suitable linkage. Failure to attain the visual lock indication signals that a further nudge of the module is needed on the side not visibly locked. Adequately applied, this further motion will result in full engagement with visual lock verification. Thus, a reliable positive coupling can be simply achieved and verified without assembly tools and without the need for an experienced installer.
Removal of the upper module from the base module 230 is just as simple. First, as shown in
After catch decoupling device 700 is actuated, the hinge assembly 400 is free to be removed by application of force F3 as shown in
An exemplary catch decoupling device 700 will be described with reference to
Catches 530 are pivotally mounted within catch decoupling device 700. Catch decoupling device 700 is preferably formed from a base 710 having a U-shaped channel. Opening 715 selectively receives visual indicator 600 therethrough while openings 720 allow catches 530 to extend therethrough. Pivot shaft 570 is fixedly mounted to a frame of base module 230 (unshown) through elongated slots 725 of the device 700. This allows for sliding movement of the base 710 of device 700 relative to the pivot shaft 570 and biased catches 530. Base 710 is preferably biased to a first position by a suitable biasing force, such as by spring 730. Base 710 also includes an inclined plane ramp structure provided on the side profile of the device. In a preferred embodiment, the ramp structure includes a main ramp profile 735 and a much smaller secondary ramp profile 740. However, the second ramp profile could be formed by a notch. Lateral movement of device 700 can be achieved, for example, by inserting a small object such as an Allen wrench or pen into pull feature 750. Alternatively, a release handle or external tab could be provided as a pull feature for manual manipulation of the device 700.
Specific details of an exemplary implementation of the catch decoupling device 700 will be described with reference to
When it is desired to decouple the hinge assembly, pull feature 750 is manipulated to slide catch decoupling device 700 in the direction of the arrow in
The exemplary embodiments as set forth above are intended to be illustrative, not limiting. Various changes may be made without departing from the spirit and scope of the invention. For example, although preferred embodiments show use of a hinge assembly 400, the upper module 220 does not need to have hinging features. Rather, the coupling mechanism may just provide quick coupling and release of the two independent module components. Therefore, the claimed systems and methods are intended to embrace all known, or later-developed, alternatives, modifications, variations, and/or improvements.
Jones, Brent R., Nelson, Aaron T., Kong, Wai Ki, Sia, Yin M.
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